Reduction of 15-hydroxyeicosatetraenoic acid (15-HETE) in tracheal fluid by high frequency oscillatory ventilation

The effects of high frequency oscillatory ventilation (HFOV) and conventional mechanical ventilation (CMV) on tracheal secretion were compared in 6 anesthetized dogs. Using a double-balloon endotracheal catheter, 5 ml of saline was instilled into an isolated tracheal segment during HFOV and CMV for 10 min respectively. Two eicosanoids, 15-hydroxyeicosatetraenoic acid (15-HETE) and 11-dehydrothromboxane B2 (11-dehydro-TXB2) were measured by radioimmunoassay in each sample. HFOV (stroke volume: 6 ml/kg, f: 10 Hz, bias flow: 5 l/min) and CMV (stroke volume: 12 ml/kg, f: 15/min) were performed in random sequence and achieved comparable gas exchange. The concentration of 15-HETE in tracheal fluid during HFOV (87 +/- 67 pg/ml) was decreased to less than half of that during CMV (286 +/- 184 pg/ml, P less than 0.05), while there was no significant change of 11-dehydro-TXB2 either in tracheal fluid or in plasma. This reduction of 15-HETE was tended to be enhanced by vagotomy (HFOV: 42 +/- 14, CMV: 120 +/- 103 pg/ml) with the concentration ratio of CMV/HFOV remaining unchanged. HFOV may provide hitherto unrecognized advantage over CMV by reducing airway secretion of 15-HETE, a potent inflammatory mediator.     

Effect of high-frequency ventilation on gas exchange and pulmonary vascular resistance in lambs

We studied the effects of conventional mechanical ventilation (CMV) (15 ml/kg tidal volume delivered at 18-25 breaths/min) and high-frequency oscillatory ventilation (HFOV) (less than or equal to 2 ml/kg delivered at 10 Hz) on pulmonary hemodynamics and gas exchange during ambient air breathing and hypoxic gas breathing in 10 4-day-old lambs. After instrumentation and randomization to either HFOV or CMV the animals breathed first ambient air and then hypoxic gas (inspired O2 fraction = 0.13) for 20 min. The mode of ventilation was then changed, and the normoxic and hypoxic gas challenges were repeated. The multiple inert gas elimination technique was utilized to assess gas exchange. There was a significant increase with HFOV in mean pulmonary arterial pressure (Ppa) (20.1 +/- 4.2 vs. 22 +/- 3.8 Torr, CMV vs. HFOV, P less than 0.05) during ambient air breathing. During hypoxic gas breathing Ppa was also greater with HFOV than with CMV (29.5 +/- 5.7 vs. 34 +/- 3.1 Torr, CMV vs. HFOV, P less than 0.05). HFOV reduced pulmonary blood flow (Qp) during ambient air breathing (0.33 +/- 0.11 vs. 0.28 +/- 0.09 l . kg-1 . min-1, CMV vs. HFOV, P less than 0.05) and during hypoxic gas breathing (0.38 +/- 0.11 vs. 0.29 +/- 0.09 l . kg-1 . min-1, P less than 0.05). There was no significant difference in calculated venous admixture for sulfur hexafluoride or in the index of low ventilation-perfusion lung regions with HFOV compared with CMV.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sustained inflation and incremental mean airway pressure trial during conventional and high-frequency oscillatory ventilation in a large porcine model of acute respiratory distress syndrome

Background

To compare the effect of a sustained inflation followed by an incremental mean airway pressure trial during conventional and high-frequency oscillatory ventilation on oxygenation and hemodynamics in a large porcine model of early acute respiratory distress syndrome.

Methods

Severe lung injury (Ali) was induced in 18 healthy pigs (55.3 ± 3.9 kg, mean ± SD) by repeated saline lung lavage until PaO₂ decreased to less than 60 mmHg. After a stabilisation period of 60 minutes, the animals were randomly assigned to two groups: Group 1 (Pressure controlled ventilation; PCV): FIO₂ = 1.0, PEEP = 5 cmH₂O, V_T = 6 ml/kg, respiratory rate = 30/min, I:E = 1:1; group 2 (High-frequency oscillatory ventilation; HFOV): FIO₂ = 1.0, Bias flow = 30 l/min, Amplitude = 60 cmH₂O, Frequency = 6 Hz, I:E = 1:1. A sustained inflation (SI; 50 cmH₂O for 60s) followed by an incremental mean airway pressure (mPaw) trial (steps of 3 cmH₂O every 15 minutes) were performed in both groups until PaO₂ no longer increased. This was regarded as full lung inflation. The mPaw was decreased by 3 cmH₂O and the animals reached the end of the study protocol. Gas exchange and hemodynamic data were collected at each step.

Results

The SI led to a significant improvement of the PaO₂/FiO₂-Index (HFOV: 200 ± 100 vs. PCV: 58 ± 15 and T_Ali: 57 ± 12; p < 0.001) and PaCO₂-reduction (HFOV: 42 ± 5 vs. PCV: 62 ± 13 and T_Ali: 55 ± 9; p < 0.001) during HFOV compared to lung injury and PCV. Augmentation of mPaw improved gas exchange and pulmonary shunt fraction in both groups, but at a significant lower mPaw in the HFOV treated animals. Cardiac output was continuously deteriorating during the recruitment manoeuvre in both study groups (HFOV: T_Ali: 6.1 ± 1 vs. T₇₅: 3.4 ± 0.4; PCV: T_Ali: 6.7 ± 2.4 vs. T₇₅: 4 ± 0.5; p < 0.001).

Conclusion

A sustained inflation followed by an incremental mean airway pressure trial in HFOV improved oxygenation at a lower mPaw than during conventional lung protective ventilation. HFOV but not PCV resulted in normocapnia, suggesting that during HFOV there are alternatives to tidal ventilation to achieve CO₂-elimination in an "open lung" approach.     

Comparison of serum levels of seven cytokines in premature newborns undergoing different ventilatory procedures: high frequency oscillatory ventilation or synchronized intermittent mandatory ventilation

OBJECTIVE: The severity of pulmonary dysfunction and subsequent development of chronic lung disease (CLD) in preterm neonates depends on several factors, among them oxygen administration. The aim of this report is to compare the effects of high-frequency, oscillatory ventilation (HFOV) versus synchronized, intermittent, mandatory ventilation (sIMV) on serum cytokine levels (IL-6, IL-8, IL-10, MCP-1, PDGF-BB, VEGF and TGF-beta1) and ventilator indices during the first week of life. Moreover, CLD development and several other outcomes were compared between the two groups. DESIGN: Randomized clinical trial. SETTING: Third level NICU. PATIENTS: 40 preterm neonates with a gestational age between 24 and 29 weeks were randomly (20 per group) assigned to one of the two, above-mentioned ventilation strategies within 30 minutes of birth. MEASUREMENTS AND RESULTS: At 1, 3 and 5 days, neonates were monitored by means of ventilator indices and levels of seven pro-inflammatory or anti-inflammatory (pro-fibrotic) cytokines in serum. No clinical or biochemical differences were observed at baseline. The neonates assigned to HFOV benefited from early and sustained improvement in gas exchange, with earlier extubation and lower incidence of CLD, as compared to the neonates assigned to sIMV treatment, and showed a significant reduction of serum IL-6, IL-8 and IL-10 over time only when the HFOV treatment was administered. In addition, at days 3 and 5, the IL-6 levels were significantly lower in the HFOV group as compared to sIMV patients. CONCLUSIONS: The results of this randomized clinical trial support the hypothesis that early use of HFOV, combined with an optimum volume strategy, has a beneficial effect, reducing serum levels of pro-inflammatory cytokines and consequently the acute phase leading to lung injury.     

Collateral ventilation during high-frequency oscillation in dogs

Mechanics of collateral channels during high-frequency oscillatory ventilation (HFOV) were assessed in eight anesthetized dogs, using a modification of Hilpert's technique. Base-line functional residual capacity was measured with a body plethysmograph, with inspiratory efforts induced by phrenic nerve stimulation. The resistance (Rcoll) and time constant (Tcoll) of collateral channels at five lung volumes were measured during HFOV and positive end-expiratory pressure (PEEP). Rcoll and Tcoll were significantly higher during HFOV (P less than 0.001); the differences did not correlate with resting lung volumes. The calculated static compliance of the wedged segment was similar during HFOV and PEEP (P greater than 0.005). Mean pressures measured in small airways during HFOV corresponded to the midline between the inflation and deflation limbs of the static pressure-volume curves, indicating similar pressure-volume characteristics of the respiratory system during HFOV and static conditions. We conclude that HFOV increases resistance to gas flow through collateral channels but that this pathway may still be important in gas exchange.     

Comparison of lung protection strategies using conventional and high-frequency oscillatory ventilation.

This study compared pathophysiological and biochemical indexes of acute lung injury in a saline-lavaged rabbit model with different ventilatory strategies: a control group consisting of moderate tidal volume (V(T)) (10-12 ml/kg) and low positive end-expiratory pressure (PEEP) (4-5 cmH(2)O); and three protective groups: 1) low V(T) (5-6 ml/kg) high PEEP, 2-3 cmH(2)O greater than the lower inflection point; 2) low V(T) (5-6 ml/kg), high PEEP (8-10 cmH(2)O); and 3) high-frequency oscillatory ventilation (HFOV). The strategy using PEEP > inflection point resulted in hypotension and barotrauma. HFOV attenuated the decrease in pulmonary compliance, the lung inflammation assessed by polymorphonuclear leukocyte infiltration and tumor necrosis factor-alpha concentration in the alveolar space, and pathological changes of the small airways and alveoli. Conventional mechanical ventilation using lung protection strategies (low V(T) high PEEP) only attenuated the decrease in oxygenation and pulmonary compliance. Therefore, HFOV may be a preferable option as a lung protection strategy.     

Benzamil, a blocker of epithelial Na(+) channel-induced upregulation of artery oxygen pressure level in acute lung injury rabbit ventilated with high frequency oscillation

The epithelial Na(+) transport via an epithelial Na(+) channel (ENaC) expressed in the lung epithelium would play a key role in recovery from lung edema at acute lung injury by removing the fluid in lung luminal space. The lung edema causes dysfunction of gas exchange, decreasing oxygen pressure level of artery [P(aO(2))]. To study if ENaC plays a key role in recovering P(aO(2)) from a decreased level to a normal one in acute lung injury, we applied benzamil (20microM, a specific blocker of ENaC) to the lung luminal space in acute lung injury treated with high frequency oscillation ventilation (HFOV) that is a lung-protective ventilation with a lower tidal volume and a smaller pressure swing than conventional mechanical ventilation (CMV). Benzamil facilitated the recovery of P(aO(2)) in acutely injured lung with HFOV but not CMV. The observation suggests that in acutely injured lung treated with HFOV an ENaC blocker, benzamil, can be applied as a therapeutic drug for acute lung injury combing with HFOV.     

Biomarkers for oxidative stress in acute lung injury induced in rabbits submitted to different strategies of mechanical ventilation

Oxidative damage has been said to play an important role in pulmonary injury, which is associated with the development and progression of acute respiratory distress syndrome (ARDS). We aimed to identify biomarkers to determine the oxidative stress in an animal model of acute lung injury (ALI) using two different strategies of mechanical ventilation. Rabbits were ventilated using either conventional mechanical ventilation (CMV) or high-frequency oscillatory ventilation (HFOV). Lung injury was induced by tracheal saline infusion (30 ml/kg, 38°C). In addition, five healthy rabbits were studied for oxidative stress. Isolated lymphocytes from peripheral blood and lung tissue samples were analyzed by alkaline single cell gel electrophoresis (comet assay) to determine DNA damage. Total antioxidant performance (TAP) assay was applied to measure overall antioxidant performance in plasma and lung tissue. HFOV rabbits had similar results to healthy animals, showing significantly higher antioxidant performance and lower DNA damage compared with CMV in lung tissue and plasma. Total antioxidant performance showed a significant positive correlation (r = 0.58; P = 0.0006) in plasma and lung tissue. In addition, comet assay presented a significant positive correlation (r = 0.66; P = 0.007) between cells recovered from target tissue and peripheral blood. Moreover, antioxidant performance was significantly and negatively correlated with DNA damage (r = -0.50; P = 0.002) in lung tissue. This study indicates that both TAP and comet assay identify increased oxidative stress in CMV rabbits compared with HFOV. Antioxidant performance analyzed by TAP and oxidative DNA damage by comet assay, both in plasma, reflects oxidative stress in the target tissue, which warrants further studies in humans.     

羧甲司坦通过巯基上调HDAC2 抑制气道炎症

目的:探究羧甲司坦(carbocysteine,S-CMC)在气道炎症中对组蛋白去乙酰化酶2(histone deacetylase2,HDAC2)表达的调控作用和机制。方法:建立脂多糖(lipopolysaccharide,LPS)诱导大鼠肺泡巨噬细胞(NR8383)炎症模型、短期烟熏Sprague Dawely(SD)大鼠气道炎症模型,采用酶联免疫吸附测定法(enzyme-linked immunosorbent assay,ELISA)检测炎症因子白细胞介素6(interleukin-6,IL-6)和白细胞介素8(interleukin-8,IL-8)的水平,蛋白免疫印迹(Western blotting)及免疫组化染色检测HDAC2的表达。结果:与对照组相比,模型组NR8383细胞中HDAC2的表达明显降低至对照组的0.47±0.11倍,细胞上清IL-6、IL-8水平明显升高,分别为157.6±15.0 pg/m L、378.0±17.9 pg/m L;模型组SD大鼠肺组织中HDAC2的表达明显降低到对照组的0.42±0.12倍,气道灌洗液(bronchoalveolar lavage fluid,BALF)中IL-6、IL-8分别为162.2±51.4 pg/m L、331.4±62.7 pg/m L,炎症因子水平明显升高。而与模型组比较,经S-CMC处理后细胞中HDAC2表达明显上调至对照组的1.23±0.05倍,细胞上清中IL-6为92.3±4.3 pg/m L,IL-8为300.7±17.7 pg/m L,炎症因子水平降低;肺组织中HDAC2为对照组的0.78±0.10倍,表达水平明显升高,BALF中IL-6、IL-8水平分别为100.6±32.7 pg/m L,185.0±50.4 pg/m L(P0.05)炎症因子明显降低。组蛋白去乙酰化酶抑制剂曲古抑霉素A(trichostatin,TSA)能够抑制NR8383细胞中HDAC2的表达至对照组的0.19±0.06倍,增加IL-6(197.0±42.6 pg/m L)、IL-8(567.0±97.4 pg/m L)水平,该作用可以被S-CMC所逆转(P0.05)。另外,加入巯基供体二硫苏糖醇(dithiothreitol,DTT)可增强S-CMC上调HDAC2表达,降低IL-6、IL-8的作用,而巯基耗竭剂丁硫氨酸亚砜亚胺(buthionine-sulfoximine,BSO)可减弱S-CMC的作用(P0.05)。进一步表明S-CMC调控HDAC2的过程与巯基相关。结论:S-CMC可通过巯基上调HDAC2的表达抑制气道炎症。     

Continuous tracheal gas insufflation during partial liquid ventilation in juvenile rabbits with acute lung injury.

To examine the hypothesis that combined treatment with tracheal gas insufflation (TGI) and partial liquid ventilation (PLV) may improve pulmonary outcome relative to either treatment alone in acute lung injury (ALI), saline lavage lung injury was induced in 24 anesthetized, ventilated juvenile rabbits that were then randomly assigned to receive (n = 6/group) 1) conventional mechanical ventilation (CMV) alone, 2) continuous TGI at 0.5 l/min, 3) PLV with perfluorochemical liquid, and 4) combined TGI and PLV (TGI + PLV), and subsequently ventilated with minimized pressures and tidal volume (Vt) to keep arterial Po(2) (Pa(O(2))) >100 Torr and arterial Pco(2) (Pa(CO(2))) at 45-60 Torr for 4 h. Gas exchange, lung mechanics, myeloperoxidase, IL-8, and histomorphometry [including expansion index (EI)] were assessed. The CMV group showed no improvement in lung mechanics and gas exchange; all treated groups had significant increases in compliance, Pa(O(2)), ventilation efficacy index (VEI), and EI, and decreases in PaCO(2), oxygenation index, physiological dead space-to-Vt ratio (Vd/Vt), myeloperoxidase, and IL-8, relative to the CMV group. TGI resulted in lower peak inspiratory pressure, Vt, Vd/Vt, and greater VEI vs. PLV group; PLV resulted in greater compliance, Pa(O(2)), and EI vs. TGI. TGI + PLV resulted in decreased peak inspiratory pressure, Vt, Vd/Vt, and increased VEI compared with TGI, improved compliance and EI compared with PLV, and a further increase in Pa(O(2)) and oxygenation index and a decrease in PaCO(2) vs. either treatment alone. These results indicate that combined treatment of TGI and PLV results in improved pulmonary outcome than either treatment alone in this animal model of ALI.     

Positive end-expiratory pressure and surfactant decrease lung injury during initiation of ventilation in fetal sheep

The initiation of ventilation in preterm, surfactant-deficient sheep without positive end-expiratory pressure (PEEP) causes airway injury and lung inflammation. We hypothesized that PEEP and surfactant treatment would decrease the lung injury from initiation of ventilation with high tidal volumes. Fetal sheep at 128-day gestational age were randomized to ventilation with: 1) no PEEP, no surfactant; 2) 8-cmH(2)O PEEP, no surfactant; 3) no PEEP + surfactant; 4) 8-cmH(2)O PEEP + surfactant; or 5) control (2-cmH(2)O continuous positive airway pressure) (n = 6-7/group). After maternal anesthesia and hysterotomy, the head and chest were exteriorized, and the fetus was intubated. While maintaining placental circulation, the fetus was ventilated for 15 min with a tidal volume escalating to 15 ml/kg using heated, humidified, 100% nitrogen. The fetus then was returned to the uterus, and tissue was collected after 30 min for evaluation of early markers of lung injury. Lambs receiving both surfactant and PEEP had increased dynamic compliance, increased static lung volumes, and decreased total protein and heat shock proteins 70 and 60 in bronchoalveolar lavage fluid compared with other groups. Ventilation, independent of PEEP or surfactant, increased mRNA expression of acute phase response genes and proinflammatory cytokine mRNA in the lung tissue compared with controls. PEEP decreased mRNA for cytokines (2-fold) compared with groups receiving no PEEP. Surfactant administration further decreased some cytokine mRNAs and changed the distribution of early growth response protein-1 expression. The use of PEEP during initiation of ventilation at birth decreased early mediators of lung injury. Surfactant administration changed the distribution of injury and had a moderate additive protective effect.     

The role of ventilation frequency in airway reopening

Inhomogeneously compliant lungs need special treatment during ventilation as they are often affected by respiratory insufficiency which is frequently caused by a regional collapse of the airways. To treat respiratory insufficiency atelectatic areas have to be recruited. Beside conventional mechanical ventilation, high-frequency oscillatory ventilation (HFOV) is an efficient method for airway reopening. Using a transparent in-vitro model of the human lung the influence of varying frequencies on the reopening behavior of atelectatic regions is investigated for volume controlled ventilation. The experiments show that higher ventilation frequencies at constant tidal volume enhance the probability of successful reopening of collapsed lung regions and thus, lead to a more homogeneous distribution of air within the lung. This effect can be attributed (i) to larger flow velocities and thus larger pressure losses in the free pathways as the ventilation frequency increases and (ii) to higher inertia effects. In consequence, the static pressure in the branches above the atelectatic regions increases until it reaches a level at which recruitment is achieved.     

Effects of high-frequency oscillatory ventilation on vagal and phrenic nerve activities

This study was undertaken to define the mechanism for the respiratory inhibition observed during high-frequency oscillatory ventilation (HFOV). The effects of HFOV on the activities of single units in the vagus (Vna) and phrenic nerves (Pna) were examined in pentobarbital-anesthetized dogs. The animals were either ventilated by intermittent positive-pressure ventilation (IPPV) with and without positive end-expiratory pressure (PEEP), or by HFOV at a frequency of 25 Hz and pump displacement volume of 3 ml/kg. In 13 vagal units the Vna was much higher during HFOV than during IPPV or airway occlusion at a matched airway pressure. Ten units in the phrenic nerves were examined, and Pna (expressed as bursts/min) was attenuated by HFOV in all of them. In four of them, the effect of cooling the vagi to 8-10 degrees C on Pna was examined, and it was found that HFOV failed to alter the Pna. We conclude that 1) HFOV stimulates the pulmonary vagal afferent fibers continuously and to a degree greater than that due to static lung inflation and increased airway pressure and 2) the increased vagal activity during HFOV probably causes phrenic nerve activity inhibition.     

Effect of lung volume on ventilation distribution

To examine the effect of preinspiratory lung volume (PILV) on ventilation distribution, we performed multiple-breath N2 washouts (MBNW) in seven normal subjects breathing 1-liter tidal volumes over a wide range of PILV above closing capacity. We measured the following two independent indexes of ventilation distribution from the MBNW: 1) the normalized phase III slope of the final breaths of the washout (Snf) and 2) the alveolar mixing efficiency during that portion of the washout where 80-90% of the lung N2 had been cleared. Three of the subjects also performed single-breath N2 washouts (SBNW) by inspiring 1-liter breaths and expiring to residual volume at PILV = functional residual capacity (FRC), FRC + 1.0, and FRC - 0.5, respectively. From the SBNW we measured the phase III slope over the expired volume ranges of 0.75-1.0, 1.0-1.6, and 1.6-2.2 liters (S0.75, S1.0, and S1.6, respectively). Between a PILV of 0.92 +/- 0.09 (SE) liter above FRC and a PILV of 1.17 +/- 0.43 liter below FRC, Snf decreased by 61% (P less than 0.001) and alveolar mixing efficiency increased from 80 to 85% (P = 0.05). In addition, Snf and alveolar mixing efficiency were negatively correlated (r = 0.74). In contrast, over a similar volume range, S1.0 and S1.6 were greater at lower PILV. We conclude that, during tidal breathing in normal subjects, ventilation distribution becomes progressively more inhomogeneous at higher lung volumes over a range of volumes above closing capacity.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-frequency oscillatory ventilation increases canine pulmonary epithelial permeability

To investigate the effect of high-frequency oscillatory ventilation (HFOV) on the pulmonary epithelial permeability, we measured the clearance rate of nebulized sodium pertechnetate (99mTcO4-) and diethylenetriaminepentaacetate (99mTc-DTPA) before and after a 4-h period of mechanical ventilation in anesthetized mongrel dogs. The animals also underwent experiments with 4 h of spontaneous breathing (SB) and intermittent positive-pressure ventilation (IPPV) with and without addition of positive end-expiratory pressure (PEEP) for comparison. After IPPV and SB there was no change in the clearance rate of either 99mTcO4- or 99mTc-DTPA. After IPPV + PEEP and HPOV (8 and 16 Hz), there was an increase in the clearance rate of 99mTc-DTPA, but an increase in clearance rate of 99mTcO4- was seen after IPPV + PEEP only. In a separate group of dogs an increase in end-tidal lung volume was demonstrated after 4 h of ventilation with IPPV + PEEP (but not after HFOV), and this may account for the measured increase in 99mTcO4- clearance. We conclude that an increase in 99mTc-DTPA clearance rate after HFOV signifies an increase in pulmonary epithelial permeability, possibly through the mechanism of damage to the intercellular junctions during HFOV.     

Stretch and CO2 modulate the inflammatory response of alveolar macrophages through independent changes in metabolic activity

Ventilatory-induced strain can exacerbate acute lung injury (ALI). Current ventilation strategies favour low tidal volumes and high end-expiratory volumes to 'rest' the lung, but can lead to an increase in CO2. Alveolar macrophages (AM) play a pivotal role in ALI through the release of inflammatory mediators. The effect of physical strain and CO2 on the release of pro-inflammatory mediators was examined in isolated rat AM. AM were cultured on IgG-coated silastic membranes with or without lipopolysaccharide (LPS) and 5% or 20% CO2 and subjected to a repetitive sinusoidal mechanical strain (30%, 60 cycles/min) for 4 h. Cell viability and metabolic activity were assessed. In both the presence and absence of LPS, physical strain increased metabolic activity by approximately 5%, while 20% CO2 decreased metabolic activity by approximately 40%. Twenty per cent CO2 decreased TNF-alpha secretion by approximately 45%, without affecting cell viability. Physical strain enhanced LPS-induced secretion of TNF-alpha by 1.5%, but not IL-6 or CINC-1. Hence, the effects of both CO2 and physical strain are mediated independently through changes in AM metabolic activity. Physical strain is not a major determinant of TNF-alpha, IL-6 or CINC-1 in AM. Our results confirm that high CO2 can lessen the TNF-alpha inflammatory response of AM.     

正常分钟通气量机械通气不同潮气量和频率影响活体山羊颈动脉血氧动态变化的初步实验研究*

目的: 在初步验证超快反应聚合物基质光纤氧传感器及其测定系统记录颈动脉氧分压（PaO₂）连续动态变化使用基础上,为了分析探讨肺通气对PaO₂连续动态变化的影响,我们设计本活体整体动物实验观察研究。方法: 选择杂种山羊4只,全身麻醉气管插管空气机械通气下,切皮直接暴露把后接测定系统的氧传感器直接插入左侧颈动脉连续记录PaO₂动态变化。正常分钟通气量机械通气分别通过三种潮气量实施：正常潮气量（潮气量VT=15 ml/kg、呼吸频率Rf=20 bpm）、减半潮气量（VT减半、Rf加倍）和加倍潮气量（VT加倍、Rf减半）。三种潮气量通气时间分别稳定10~15 min,选取后180 s分析计算PaO₂平均值、呼吸间PaO₂变化的升降幅度和肺-颈动脉延迟时间。以ANOVA及两两比较统计学差异分析不同潮气量的影响。结果: 活体山羊正常通气量机械通气实验时心率和血压均稳定;肺-颈动脉延迟时间为1.4~1.8 s（约为此时的3次心跳）。机械通气正常潮气量下PaO₂平均值在（102.94±2.40,99.38~106.16）mmHg,升降幅度是（21.43±1.65,19.21~23.59）mmHg,占平均值的（20.80±1.34,18.65~22.22）%;减半潮气量下,PaO₂平均值维持在（101.01±4.25,94.09~105.66）mmHg,虽略降但不显著（与正常机械通气比较P>0.05）,但PaO₂升降变化幅度却显著降低为（18.14±1.43,16.46~20.05） mmHg,占平均值的（17.95±1.07,16.16~18.98）%（与正常机械通气比较P<0.01）;加倍潮气量机械通气下,虽仅略升的PaO₂平均值维持在（106.42±4.74,101.19~114.08）mmHg（与正常机械通气比较P>0.05,与减半潮气量机械通气比较P<0.05）,但PaO₂升降幅度却显著增大为（26.58±1.88,23.46~28.46）mmHg,占平均值的24.99%±1.58%（与正常机械通气和减半潮气量比较P均<0.01）。结论: 正常肺通气的吸气和呼气是颈动脉PaO₂上升和下降的始动因素。正常通气量机械通气下减半潮气量和倍增潮气量显著改变PaO₂升降幅度,但PaO₂平均值仅小幅改变,而肺-颈动脉延迟时间相近。     

Effect of lung-protective ventilation with lower tidal volumes on clinical outcomes among patients undergoing surgery: a meta-analysis of randomized controlled trials

Background:In anesthetized patients undergoing surgery, the role of lung-protective ventilation with lower tidal volumes is unclear. We performed a meta-analysis of randomized controlled trials (RCTs) to evaluate the effect of this ventilation strategy on postoperative outcomes.Methods:We searched electronic databases from inception through September 2014. We included RCTs that compared protective ventilation with lower tidal volumes and conventional ventilation with higher tidal volumes in anesthetized adults undergoing surgery. We pooled outcomes using a random-effects model. The primary outcome measures were lung injury and pulmonary infection.Results:We included 19 trials (n = 1348). Compared with patients in the control group, those who received lung-protective ventilation had a decreased risk of lung injury (risk ratio [RR] 0.36, 95% confidence interval [CI] 0.17 to 0.78; I² = 0%) and pulmonary infection (RR 0.46, 95% CI 0.26 to 0.83; I² = 8%), and higher levels of arterial partial pressure of carbon dioxide (standardized mean difference 0.47, 95% CI 0.18 to 0.75; I² = 65%). No significant differences were observed between the patient groups in atelectasis, mortality, length of hospital stay, length of stay in the intensive care unit or the ratio of arterial partial pressure of oxygen to fraction of inspired oxygen.Interpretation:Anesthetized patients who received ventilation with lower tidal volumes during surgery had a lower risk of lung injury and pulmonary infection than those given conventional ventilation with higher tidal volumes. Implementation of a lung-protective ventilation strategy with lower tidal volumes may lower the incidence of these outcomes.Estimates suggest that more than 230 million patients undergo major surgical procedures worldwide each year.¹ Postoperative pulmonary complications, including lung injury, pneumonia and atelectasis, are common and a major cause of morbidity and death.^2–5 Thus, prevention of these complications has become a high priority of perioperative care.Mechanical ventilation is mandatory in patients undergoing surgical procedures during general anesthesia. Conventional mechanical ventilation with tidal volumes of 10 to 15 mL/kg has been advocated to prevent hypoxemia and atelectasis in anesthetized patients undergoing surgery.⁶ However, unequivocal evidence from experimental and clinical studies suggests that mechanical ventilation, especially the use of high tidal volumes, may cause or aggravate lung injury.^7–9 Mechanical ventilation using high tidal volumes can result in overdistention of alveoli that mainly causes ventilator-associated lung injury.¹⁰Lung-protective ventilation refers to the use of low tidal volumes and moderate to high levels of positive end-expiratory pressure, with or without a recruitment manoeuvre.¹¹ Lung-protective ventilation has been found to reduce morbidity and mortality among patients with acute lung injury and acute respiratory distress syndrome.^11,12 However, in anesthetized patients without the syndrome, the role of lung-protective ventilation remains unclear. Two previous meta-analyses addressing similar research questions have been published,^13,14 but the inclusion of observational studies compromised the reliability of the results. Recently, randomized controlled trials (RCTs) on the topic have reported conflicting results. We performed a meta-analysis of RCTs to evaluate the effect of lung-protective ventilation with lower tidal volumes on clinical outcomes in patients undergoing surgery.     

Effect of airway closure on ventilation distribution

We examined the effect of airway closure on ventilation distribution during tidal breathing in six normal subjects. Each subject performed multiple-breath N2 washouts (MBNW) at tidal volumes of 1 liter over a range of preinspiratory lung volumes (PILV) from functional residual capacity (FRC) to just above residual volume. All subjects performed washouts at PILV below their measured closing capacity. In addition five of the subjects performed MBNW at PILV below closing capacity with end-inspiratory breath holds of 2 or 5 s. We measured the following two independent indexes of ventilation maldistribution: 1) the normalized phase III slope of the final breaths of the washout (Snf) and 2) the alveolar mixing efficiency of those breaths of the washout where 80-90% of the initial N2 had been cleared. Between a mean PILV of 0.28 liter above closing capacity and that 0.31 liter below closing capacity, mean Snf increased by 132% (P less than 0.005). Over the same volume range, mean alveolar mixing efficiency decreased by 3.3% (P less than 0.05). Breath holding at PILV below closing capacity resulted in marked and consistent decreases in Snf and increases in alveolar mixing efficiency. Whereas inhomogeneity of ventilation decreases with lung volume when all airways are patent (J. Appl. Physiol. 66: 2502-2510, 1989), airway closure increases ventilation inequality, and this is substantially reduced by short end-inspiratory breath holds. These findings suggest that the predominant determinant of ventilation distribution below closing capacity is the inhomogeneous closure of airways subtending regions in the lung periphery that are close together.